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\documentclass{article}
\usepackage{open-axiom}
\begin{document}
\title{\$SPAD/src/algebra mts.spad}
\author{William Burge, Stephen Watt, Clifton Williamson}
\maketitle
\begin{abstract}
\end{abstract}
\eject
\tableofcontents
\eject
\section{domain SMTS SparseMultivariateTaylorSeries}
<<domain SMTS SparseMultivariateTaylorSeries>>=
import NonNegativeInteger
import List
import Stream
)abbrev domain SMTS SparseMultivariateTaylorSeries
++ This domain provides multivariate Taylor series
++ Authors: William Burge, Stephen Watt, Clifton Williamson
++ Date Created: 15 August 1988
++ Date Last Updated: 18 May 1991
++ Basic Operations:
++ Related Domains:
++ Also See: UnivariateTaylorSeries
++ AMS Classifications:
++ Keywords: multivariate, Taylor, series
++ Examples:
++ References:
++ Description:
++ This domain provides multivariate Taylor series with variables
++ from an arbitrary ordered set. A Taylor series is represented
++ by a stream of polynomials from the polynomial domain SMP.
++ The nth element of the stream is a form of degree n. SMTS is an
++ internal domain.
SparseMultivariateTaylorSeries(Coef,Var,SMP):_
Exports == Implementation where
Coef : Ring
Var : OrderedSet
SMP : PolynomialCategory(Coef,IndexedExponents Var,Var)
I ==> Integer
L ==> List
NNI ==> NonNegativeInteger
OUT ==> OutputForm
PS ==> InnerTaylorSeries SMP
RN ==> Fraction Integer
ST ==> Stream
StS ==> Stream SMP
STT ==> StreamTaylorSeriesOperations SMP
STF ==> StreamTranscendentalFunctions SMP
ST2 ==> StreamFunctions2
ST3 ==> StreamFunctions3
Exports ==> MultivariateTaylorSeriesCategory(Coef,Var) with
coefficient: (%,NNI) -> SMP
++ \spad{coefficient(s, n)} gives the terms of total degree n.
coerce: Var -> %
++ \spad{coerce(var)} converts a variable to a Taylor series
coerce: SMP -> %
++ \spad{coerce(poly)} regroups the terms by total degree and forms
++ a series.
*:(SMP,%)->%
++\spad{smp*ts} multiplies a TaylorSeries by a monomial SMP.
csubst:(L Var,L StS) -> (SMP -> StS)
++\spad{csubst(a,b)} is for internal use only
if Coef has Algebra Fraction Integer then
integrate: (%,Var,Coef) -> %
++\spad{integrate(s,v,c)} is the integral of s with respect
++ to v and having c as the constant of integration.
fintegrate: (() -> %,Var,Coef) -> %
++\spad{fintegrate(f,v,c)} is the integral of \spad{f()} with respect
++ to v and having c as the constant of integration.
++ The evaluation of \spad{f()} is delayed.
Implementation ==> PS add
Rep := StS -- Below we use the fact that Rep of PS is Stream SMP.
-- FIXME: The next two functions come free if assignment to Rep is removed.
rep(x: %): Rep == x pretend Rep
per(x: Rep): % == x pretend %
extend(x,n) == extend(x,n + 1)$Rep
complete x == complete(x)$Rep
evalstream:(%,L Var,L SMP) -> StS
evalstream(s:%,lv:(L Var),lsmp:(L SMP)):(ST SMP) ==
scan(0,_+$SMP,map(eval(#1,lv,lsmp),s pretend StS))$ST2(SMP,SMP)
addvariable:(Var,InnerTaylorSeries Coef) -> %
addvariable(v,s) ==
ints := integers(0)$STT pretend ST NNI
map(monomial(#2 :: SMP,v,#1)$SMP,ints,s pretend ST Coef)$ST3(NNI,Coef,SMP)
coefficient(s:%,n: NNI) ==
elt(s,n + 1)$Rep -- 1-based indexing for streams
--% creation of series
coerce(r:Coef) == monom(r::SMP,0)$STT
smp:SMP * p:% == per((smp * rep p)$STT)
r:Coef * p:% == per(((r::SMP) * rep p )$STT)
p:% * r:Coef == per(((r::SMP) * rep p)$STT)
mts(p:SMP):% ==
(uv := mainVariable p) case "failed" => monom(p,0)$STT
v := uv :: Var
s : % := 0
up := univariate(p,v)
while not zero? up repeat
s := s + monomial(1,v,degree up) * mts(leadingCoefficient up)
up := reductum up
s
coerce(p:SMP) == mts p
coerce(v:Var) == v :: SMP :: %
monomial(r:%,v:Var,n:NNI) ==
r * monom(monomial(1,v,n)$SMP,n)$STT
--% evaluation
substvar: (SMP,L Var,L %) -> %
substvar(p,vl,q) ==
null vl => monom(p,0)$STT
(uv := mainVariable p) case "failed" => monom(p,0)$STT
v := uv :: Var
v = first vl =>
s : % := 0
up := univariate(p,v)
while not zero? up repeat
c := leadingCoefficient up
s := s + first q ** degree up * substvar(c,rest vl,rest q)
up := reductum up
s
substvar(p,rest vl,rest q)
sortmfirst:(SMP,L Var,L %) -> %
sortmfirst(p,vl,q) ==
nlv : L Var := sort(#1 > #2,vl)
nq : L % := [q position$(L Var) (i,vl) for i in nlv]
substvar(p,nlv,nq)
csubst(vl,q) == sortmfirst(#1,vl,q pretend L(%)) pretend StS
restCheck(s:StS):StS ==
-- checks that stream is null or first element is 0
-- returns empty() or rest of stream
empty? s => s
not zero? frst s =>
error "eval: constant coefficient should be 0"
rst s
eval(s:%,v:L Var,q:L %) ==
#v ~= #q =>
error "eval: number of variables should equal number of values"
nq : L StS := [restCheck(i pretend StS) for i in q]
addiag(map(csubst(v,nq),s pretend StS)$ST2(SMP,StS))$STT pretend %
substmts(v:Var,p:SMP,q:%):% ==
up := univariate(p,v)
ss : % := 0
while not zero? up repeat
d:=degree up
c:SMP:=leadingCoefficient up
ss := ss + c* q ** d
up := reductum up
ss
subststream(v:Var,p:SMP,q:StS):StS==
substmts(v,p,q pretend %) pretend StS
comp1:(Var,StS,StS) -> StS
comp1(v,r,t)== addiag(map(subststream(v,#1,t),r)$ST2(SMP,StS))$STT
comp(v:Var,s:StS,t:StS):StS == delay
empty? s => s
f := frst s; r : StS := rst s;
empty? r => s
empty? t => concat(f,comp1(v,r,empty()$StS))
not zero? frst t =>
error "eval: constant coefficient should be zero"
concat(f,comp1(v,r,rst t))
eval(s:%,v:Var,t:%) == comp(v,s pretend StS,t pretend StS)
--% differentiation and integration
differentiate(s:%,v:Var):% ==
empty? s => 0
map(differentiate(#1,v),rst s)
if Coef has Algebra Fraction Integer then
(x:%) ** (r:RN) == powern(r,rep x)$STT
(r:RN) * (x:%) == per map(r * #1, rep x)$ST2(SMP,SMP)
(x:%) * (r:RN) == per map(#1 * r,rep x )$ST2(SMP,SMP)
exp x == exp(rep x)$STF
log x == log(rep x)$STF
sin x == sin(rep x)$STF
cos x == cos(rep x)$STF
tan x == tan(rep x)$STF
cot x == cot(rep x)$STF
sec x == sec(rep x)$STF
csc x == csc(rep x)$STF
asin x == asin(rep x)$STF
acos x == acos(rep x)$STF
atan x == atan(rep x)$STF
acot x == acot(rep x)$STF
asec x == asec(rep x)$STF
acsc x == acsc(rep x)$STF
sinh x == sinh(rep x)$STF
cosh x == cosh(rep x)$STF
tanh x == tanh(rep x)$STF
coth x == coth(rep x)$STF
sech x == sech(rep x)$STF
csch x == csch(rep x)$STF
asinh x == asinh(rep x)$STF
acosh x == acosh(rep x)$STF
atanh x == atanh(rep x)$STF
acoth x == acoth(rep x)$STF
asech x == asech(rep x)$STF
acsch x == acsch(rep x)$STF
intsmp(v:Var,p: SMP): SMP ==
up := univariate(p,v)
ss : SMP := 0
while not zero? up repeat
d := degree up
c := leadingCoefficient up
ss := ss + inv((d+1) :: RN) * monomial(c,v,d+1)$SMP
up := reductum up
ss
fintegrate(f,v,r) ==
concat(r::SMP,delay map(intsmp(v,#1),f() pretend StS))
integrate(s,v,r) ==
concat(r::SMP,map(intsmp(v,#1),s pretend StS))
-- If there is more than one term of the same order, group them.
tout(p:SMP):OUT ==
pe := p :: OUT
monomial? p => pe
paren pe
showAll?: () -> Boolean
-- check a global Lisp variable
showAll?() == true
coerce(s:%):OUT ==
uu := s pretend Stream(SMP)
empty? uu => (0$SMP) :: OUT
count : NNI := _$streamCount$Lisp
l : List OUT := empty()
n : NNI := 0
while n <= count and not empty? uu repeat
if frst(uu) ~= 0 then l := concat(tout frst uu,l)
uu := rst uu
n := n + 1
if showAll?() then
while explicitEntries? uu and not eq?(uu,rst uu) repeat
if frst(uu) ~= 0 then l := concat(tout frst uu,l)
uu := rst uu
n := n + 1
l :=
explicitlyEmpty? uu => l
eq?(uu,rst uu) and frst uu = 0 => l
concat(prefix("O" :: OUT,[n :: OUT]),l)
empty? l => (0$SMP) :: OUT
reduce("+",reverse! l)
if Coef has Field then
p:% / r:Coef == per(map(#1/$SMP r,rep p)$StreamFunctions2(SMP,SMP))
@
\section{domain TS TaylorSeries}
<<domain TS TaylorSeries>>=
)abbrev domain TS TaylorSeries
++ Authors: Burge, Watt, Williamson
++ Date Created: 15 August 1988
++ Date Last Updated: 18 May 1991
++ Basic Operations:
++ Related Domains: SparseMultivariateTaylorSeries
++ Also See: UnivariateTaylorSeries
++ AMS Classifications:
++ Keywords: multivariate, Taylor, series
++ Examples:
++ References:
++ Description:
++ \spadtype{TaylorSeries} is a general multivariate Taylor series domain
++ over the ring Coef and with variables of type Symbol.
TaylorSeries(Coef): Exports == Implementation where
Coef : Ring
L ==> List
NNI ==> NonNegativeInteger
SMP ==> Polynomial Coef
StS ==> Stream SMP
Exports ==> MultivariateTaylorSeriesCategory(Coef,Symbol) with
coefficient: (%,NNI) -> SMP
++\spad{coefficient(s, n)} gives the terms of total degree n.
coerce: Symbol -> %
++\spad{coerce(s)} converts a variable to a Taylor series
coerce: SMP -> %
++\spad{coerce(s)} regroups terms of s by total degree
++ and forms a series.
if Coef has Algebra Fraction Integer then
integrate: (%,Symbol,Coef) -> %
++\spad{integrate(s,v,c)} is the integral of s with respect
++ to v and having c as the constant of integration.
fintegrate: (() -> %,Symbol,Coef) -> %
++\spad{fintegrate(f,v,c)} is the integral of \spad{f()} with respect
++ to v and having c as the constant of integration.
++ The evaluation of \spad{f()} is delayed.
Implementation ==> SparseMultivariateTaylorSeries(Coef,Symbol,SMP) add
Rep := StS -- Below we use the fact that Rep of PS is Stream SMP.
polynomial(s,n) ==
sum : SMP := 0
for i in 0..n while not empty? s repeat
sum := sum + frst s
s:= rst s
sum
@
\section{License}
<<license>>=
--Copyright (c) 1991-2002, The Numerical ALgorithms Group Ltd.
--All rights reserved.
--
--Redistribution and use in source and binary forms, with or without
--modification, are permitted provided that the following conditions are
--met:
--
-- - Redistributions of source code must retain the above copyright
-- notice, this list of conditions and the following disclaimer.
--
-- - Redistributions in binary form must reproduce the above copyright
-- notice, this list of conditions and the following disclaimer in
-- the documentation and/or other materials provided with the
-- distribution.
--
-- - Neither the name of The Numerical ALgorithms Group Ltd. nor the
-- names of its contributors may be used to endorse or promote products
-- derived from this software without specific prior written permission.
--
--THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
--IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
--TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
--PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
--OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
--EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
--PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
--PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
--LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
--NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
--SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
@
<<*>>=
<<license>>
<<domain SMTS SparseMultivariateTaylorSeries>>
<<domain TS TaylorSeries>>
@
\eject
\begin{thebibliography}{99}
\bibitem{1} nothing
\end{thebibliography}
\end{document}
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